CN216971452U - Tail glue conveying structure - Google Patents

Abstract

The utility model provides a tail rubber conveying structure, which comprises a rubber plate placing device, a rubber sticking device and an active cache device, wherein the rubber plate placing device is arranged on the tail rubber plate; the glue placing disc device is arranged on the eighth base and is used for placing a tail glue disc; the rubberizing device is connected with the eighth base, is positioned on one side of the rubber placing disc device and is used for conveying the tail rubber materials to the corresponding rubberizing platforms; the active buffer device is arranged between the rubber plate placing device and the rubber sticking device and drives the tail rubber materials to be conveyed from the rubber plate placing device to the rubber sticking device. According to the tail rubber conveying device, the active cache device is arranged between the rubber placing disc device and the rubber sticking device, and the tail rubber is actively driven to be conveyed under the condition of the tail rubber sticking operation, so that the tail rubber is prevented from being broken, the stability of the structure in use is improved, the equipment is prevented from being easily abraded due to the fact that the tail rubber of the equipment is directly pulled and driven, and the structure is good in using effect.

Description

Tail glue conveying structure

Technical Field

The utility model relates to the field of winding equipment, in particular to a tail rubber conveying structure.

Background

The material receiving part of the coil material processing production line winds raw materials into coil materials in a mechanical mode, and the coil materials are widely applied to paper rolls, cloth rolls, plastic rolls and metal coil material processing production lines.

The tail glue is pasted at material winding or needs to current receipts material machine, and current tail glue feeding structure only drives the tail glue through snatching of rubberizing manipulator and carries the operation, and the tail is glued the conveying speed instability in transportation process, easily leads to the tail to glue the fracture to reduce and wind a finished product quality, unsatisfied market demand. Therefore, it is necessary to provide a tail rubber conveying structure to solve the above technical problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a tail rubber conveying structure, which aims to solve the problems that in the prior art, a tail rubber feeding structure drives tail rubber conveying operation only through grabbing of a rubber pasting mechanical arm, the tail rubber conveying speed is unstable, and tail rubber breakage is easily caused.

In order to solve the technical problems, the technical scheme of the utility model is as follows: a tail rubber conveying structure is used for attaching tail rubber to a rolling belt material; it includes:

an eighth base, wherein the first base is provided with a plurality of grooves,

the rubber plate placing device is arranged on the eighth base and used for placing a tail rubber plate;

the rubberizing device is connected with the eighth base, is positioned on one side of the rubber placing disc device and is used for conveying the tail rubber material to the corresponding rubberizing platform; and

the active buffer device is arranged between the rubber placing disc device and the rubber pasting device and drives the tail rubber to be conveyed from the rubber placing disc device to the rubber pasting device;

wherein, the active cache device comprises:

the tail rubber driving wheel is rotationally connected with the eighth base; and

the eighth rotating motor, with eighth base fixed connection, the eighth rotating motor through the eighth hold-in range with the tail gum action wheel transmission is connected, the eighth rotating motor drive the tail gum action wheel rotates.

In the present invention, the adhesive tape sticking device includes:

the glue sucking assembly is used for clamping the tail glue stock and attaching the tail glue stock to the corresponding gluing platform;

the glue cutting assembly is arranged at one end, far away from the active caching device, of the glue sucking assembly, and the glue cutting assembly and the eighth base are used for cutting tail glue materials;

the turnover assembly is arranged on one side, away from the glue sucking assembly, of the glue cutting assembly, and the turnover assembly is used for turning over the sheared tail glue.

In the present invention, the folding assembly includes:

an eighth chuck for clamping the tail rubber material, wherein a first folding groove is arranged on the eighth chuck,

the eighth rubber pushing plate is arranged below the eighth chuck and corresponds to the first turnover groove in position; and

the eighth glue pushing cylinder is connected with the eighth base, and drives the eighth glue pushing plate to be movably connected with the first turnover groove, so that the tail glue is turned over.

In the present invention, the eighth cartridge includes:

the first folding groove is arranged on the tail rubber guide plate, a pressing plate groove is also arranged on one side of the tail rubber guide plate, the pressing plate groove is communicated with the first folding groove, the plane of the first folding groove is crossed with the plane of the pressing plate groove,

the eighth pressure head is connected with the tail rubber guide plate, and the eighth pressure head and the tail rubber guide plate move relatively to clamp the tail rubber belt; and

the eighth cylinder sets up on the tail rubber deflector, just the eighth cylinder with the eighth pressure head is connected, the eighth cylinder drive the eighth pressure head is relative the motion of tail rubber deflector.

According to the utility model, the first turnover groove is arranged at the bottom end of the tail rubber guide plate, one side of the middle part of the tail rubber guide plate is rotatably connected with the middle part of the eighth pressure head through an eighth rotating shaft, the eighth air cylinder is connected with the top end of the eighth pressure head, and the eighth air cylinder drives the eighth pressure head to rotate around the eighth rotating shaft, so that the eighth pressure head and the first turnover groove move relatively.

In the utility model, an eighth elastic piece is further arranged on one side of the tail rubber guide plate, the eighth elastic piece is positioned between the eighth rotating shaft and the first folding groove, and the eighth elastic piece elastically extrudes the bottom end of the eighth pressure head to be far away from the first folding groove. And the eighth elastic piece promotes the stability of structure in the use of eighth chuck.

In the utility model, the glue sucking component comprises:

the glue absorption pressing block is used for absorbing tail glue;

the eighth z-axis group is arranged on the eighth base and connected with the glue sucking pressing block, and the eighth z-axis group drives the glue sucking pressing block and the corresponding gluing platform to move relatively; and

the first tail rubber limiting ring is arranged between the rubber suction pressing block and the active caching device and used for guiding tail rubber materials, and the first tail rubber limiting ring is connected with the rubber suction pressing block through the first installation shaft. The fourth z-axis group drives the eighth chuck and the glue pushing assembly to move relatively, and the efficiency of the structure for turning over the tail glue material is improved.

The fourth z-axis group in the preferred embodiment is the eighth z-axis group. The eighth chuck is connected with the eighth z-axis group, the eighth z-axis group drives the glue sucking pressing block and the eighth chuck to simultaneously move relative to the corresponding glue pasting platform, the structure is compact, and the space of the device in the equipment is saved)

In the utility model, a second tail rubber limiting ring is further arranged between the first tail rubber limiting ring and the active cache device, and the second tail rubber limiting ring is rotatably connected with the eighth base. Along with eighth z axle group drives first tail and glues spacing ring up-and-down motion to make second tail glue spacing ring and first tail glue spacing ring relative motion, can carry out the tensioning to the tail sizing material, promoted the stability in the structure use.

In the utility model, the tail rubber driving wheel is detachably connected with the eighth base. The tail rubber driving wheels with different sizes can be replaced by tail rubber materials with different lengths cached as required, and the structure is strong in practicability.

In the utility model, the eighth base is also connected with a counting sensor, and the counting sensor is used for detecting the rotation stroke of the tail rubber driving wheel.

According to the utility model, the adhesive cutting assembly comprises a cutter and a cutter driving piece, the cutter is connected with the eighth base through the cutter driving piece, and the cutter driving piece drives the cutter to move relative to the adhesive pasting platform. Thereby shearing and segmenting the tail rubber material.

According to the utility model, the cutter is arranged below the tail rubber guide plate, and the tail rubber guide plate is provided with a first shearing space for accommodating the cutter.

In the utility model, the rubberizing device further comprises a rubber jacking component, and the rubber jacking component comprises:

the rubberizing top block is arranged at the bottom end of the rubberizing pressing block and used for supporting a tape material; and

the top rubber cylinder is connected with the eighth base, the top rubber cylinder is connected with the bottom end of the rubberizing ejector block, and the top rubber cylinder drives the rubberizing ejector block to move relative to the eighth chuck.

Compared with the prior art, the utility model has the beneficial effects that: the tail rubber conveying structure comprises a rubber plate placing device, a rubber sticking device and an active caching device; the glue placing disc device is arranged on the eighth base and used for placing the tail glue disc; the rubberizing device is connected with the eighth base, is positioned on one side of the glue tray placing device and is used for conveying the tail glue stock to the corresponding rubberizing platform; the active buffer device is arranged between the rubber plate placing device and the rubber pasting device and drives the tail rubber material to be conveyed from the rubber plate placing device to the rubber pasting device. According to the tail rubber conveying device, the active cache device is arranged between the rubber plate placing device and the rubber sticking device, and the tail rubber is actively driven to convey under the condition of rubber sticking operation, so that the tail rubber is prevented from being broken, the stability of the structure is improved, the equipment is prevented from being easily abraded due to the fact that the tail rubber of the equipment is directly pulled and driven, and the structure is good in using effect.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required in the embodiments are briefly introduced below, and the drawings in the following description are only corresponding to some embodiments of the present invention.

Fig. 1 is a schematic overall structure diagram of a preferred embodiment of the present invention. Fig. 2 is a cross-sectional view of a preferred embodiment of the present invention. Fig. 3 is a perspective view of the tray feeding mechanism of the preferred embodiment of the present invention. Fig. 4 is a top view of the tray feeding mechanism of the preferred embodiment of the present invention. Fig. 5 is a top view of the first rotating apparatus according to the preferred embodiment of the present invention. Fig. 6 is a schematic structural view of a first rotating device in a use state according to a preferred embodiment of the present invention. FIG. 7 is a diagram of the first bin after inversion according to the preferred embodiment of the utility model. Fig. 8 is an exploded view of the tray feeding mechanism of the preferred embodiment of the present invention. Fig. 9 is a perspective view of a transfer mechanism according to a preferred embodiment of the present invention. Fig. 10 is a side view of a transfer mechanism in accordance with a preferred embodiment of the present invention. Fig. 11 is a diagram illustrating a state where the transfer mechanism of the preferred embodiment of the present invention transfers the tray to the tray winding position. Fig. 12 is a view showing a configuration in which the transfer mechanism is in a full state in accordance with the preferred embodiment of the present invention. Fig. 13 is a perspective view of a winding mechanism according to a preferred embodiment of the present invention. Fig. 14 is a side view of the winding mechanism of the preferred embodiment of the present invention. Fig. 15 is an overall structural view of a winding mechanism according to a preferred embodiment of the present invention. Fig. 16 is a schematic structural diagram of a ninth positioning device according to a preferred embodiment of the present invention. Fig. 17 is a schematic structural view of an auxiliary winding device according to a preferred embodiment of the present invention. Fig. 18 is a perspective view of a coil feeding mechanism according to a preferred embodiment of the present invention. Fig. 19 is a side view of a roll feed mechanism in accordance with a preferred embodiment of the present invention. Fig. 20 is a schematic view of a seventh guide rail assembly according to a preferred embodiment of the present invention.

Fig. 21 is a schematic cross-sectional structure view of a taping device in accordance with a preferred embodiment of the present invention. Fig. 22 is a schematic view of a rubberizing state structure of a rubberizing apparatus according to a preferred embodiment of the present invention. Fig. 23 is a schematic structural view of a feeding manipulator according to a preferred embodiment of the present invention. Fig. 24 is a perspective view of a loading robot in accordance with a preferred embodiment of the present invention. Fig. 25 is a schematic structural view of a blanking mechanism according to a preferred embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the drawings, elements having similar structures are denoted by the same reference numerals.

The terms "first," "second," and the like in the terms of the utility model are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or any order limitation.

Referring to fig. 1, 2 and 18, a preferred embodiment of a tail rubber conveying structure according to the present invention is described as follows. The preferred embodiment of the tail rubber conveying structure provided by the utility model is applied to the integrated material receiving machine, and the following detailed explanation is given by taking the structure of the integrated material receiving machine as an example:

an integrated material receiving machine using a tail rubber conveying structure; the automatic feeding device comprises a box body 3, a transfer mechanism 2, a material tray feeding mechanism 1, a winding mechanism 5, a coil feeding mechanism 5 and a discharging mechanism 4. The box 3 is a hollow structure, and the box 3 is sequentially provided with an empty disc area, a winding area and a finished product area from top to bottom.

Transfer mechanism 2 sets up in 3 one ends of box, and transfer mechanism 2 is used for carrying the charging tray from charging tray feed mechanism 1 to the charging tray, and transfer mechanism 2 includes the drive arrangement who is used for grafting plug rod part 23 and the motion of drive plug rod part 23 of charging tray, includes first material loading charging tray rolling position and full material unloading position on the track of 23 motion of plug rod part.

The material tray feeding mechanism 1 is arranged in an empty tray area in a sliding mode and used for conveying a material tray to a first material loading position. The winding mechanism 5 is arranged in the winding area and located below the feeding disc mechanism, and the winding mechanism 5 is used for winding the material disc and the coiled material so as to form full material. Coil stock feed mechanism 5 sets up in around regional one side of rolling up, and coil stock feed mechanism 5 is connected with box 3, and coil stock feed mechanism 5 is used for carrying the coil stock around rolling up mechanism 5. The blanking mechanism 4 is arranged in a finished product area in a sliding mode, the blanking mechanism 4 is located below the winding mechanism 5, and the blanking mechanism 4 is used for outputting full materials located at a full material blanking position.

The integrated material receiving machine adopts the feeding and discharging of a sliding drawer type structure, so that the structure compactness of the material receiving machine is improved; and from the vertical equipment structure down, further make full use of the vertical space of equipment, reduced the area of equipment, the structure practicality is strong.

Referring to fig. 18, in the present invention, the web includes a web material and a tail rubber material adhered to the web material. The coil feeding mechanism 5 comprises an eighth base 51, a feeding manipulator 73, a coil conveying structure 7 and a tail rubber conveying structure 6; the eighth base 51 is connected to the case 3; the feeding manipulator 73 is connected with the eighth base 51, and the feeding manipulator 73 is used for guiding and conveying the coil to the winding mechanism 5; the coiled material conveying structure 7 is connected with the eighth base 51, and the coiled material conveying structure 7 is used for conveying the coiled material to the feeding manipulator 73; the tail rubber conveying structure 6 is connected with the eighth base 51, the tail rubber conveying structure 6 is located between the tape material conveying structure 7 and the feeding manipulator 73, the tail rubber conveying structure 6 is used for attaching tail rubber to tape materials, and the tail rubber carries out sealing of the tape materials wound.

The tail rubber conveying structure 6 in the present embodiment is explained in detail with reference to fig. 19, 21, and 22:

the tail rubber conveying structure 6 comprises a rubber plate placing device 61, a rubber sticking device 62 and an active buffer device 63; the glue tray placing device 61 is arranged on the eighth base 51, and the glue tray placing device 61 is used for placing a tail glue tray; the rubberizing device 62 is connected with the eighth base 51, is located on one side of the rubber placing disc device 61, and is used for conveying tail rubber materials to a corresponding rubberizing platform; the active buffer device 63 is arranged between the rubber plate placing device 61 and the rubber coating device 62, and the active buffer device 63 drives the tail rubber to be conveyed from the rubber plate placing device 61 to the rubber coating device 62.

Preferably, the rubberizing platform in this embodiment is a plane where the tape material is located.

According to the tail rubber conveying device, the active buffer device 63 is arranged between the rubber plate placing device 61 and the rubber sticking device 62, and the tail rubber is actively driven to convey under the condition of rubber sticking operation along with the tail rubber, so that the tail rubber is prevented from being broken, the stability of structural use is improved, the equipment is prevented from being easily abraded due to the fact that the tail rubber of the equipment is directly pulled and driven, and the structural use effect is good.

The coil feeding mechanism 5 of the present invention is explained with reference to fig. 13 to 24:

in the present invention, the active buffer device 63 includes a tail rubber driving wheel 631 and an eighth rotating motor 632; wherein the tail rubber driving wheel 631 is rotatably connected with the eighth base 51; the eighth rotating motor 632 is fixedly connected to the eighth base 51, the eighth rotating motor 632 is in transmission connection with the tail rubber driving wheel 631 through an eighth synchronous belt, and the eighth rotating motor 632 drives the tail rubber driving wheel 631 to rotate.

The structure of the rubberizing device 62 of the present invention is explained in detail:

the rubberizing device 62 comprises a glue sucking component 621, a glue cutting component 622, a folding component 623 and a glue ejecting component 625; the glue sucking component 621 is used for clamping the tail glue stock and attaching the tail glue stock to a corresponding gluing platform; the rubber cutting component 622 is arranged at one end, far away from the active cache device 63, of the rubber suction component 621, and the rubber cutting component 622 and the eighth base 51 are used for cutting tail rubber materials; the turnover component 623 is arranged on one side, away from the glue sucking component 621, of the glue cutting component 622, and the turnover component 623 is used for turning over the sheared tail glue, so that the full material can be conveniently used.

In the present invention, the turnover assembly 623 comprises an eighth chuck 6231, an eighth glue pushing plate 6238 and an eighth glue pushing cylinder 6239; the eighth chuck 6231 is used for clamping the tail rubber, the eighth chuck 6231 is provided with a first folding groove 6232a, the eighth rubber pushing plate 6238 is arranged below the eighth chuck 6231, and the eighth rubber pushing plate 6238 corresponds to the first folding groove 6232 a; the eighth glue pushing cylinder 6239 is connected to the eighth base 51, and the eighth glue pushing cylinder 6239 drives the eighth glue pushing plate 6238 to be movably connected to the first folding groove 6232a, so as to fold the tail glue.

In this embodiment, the eighth collet 6231 includes a tail rubber guide plate 6232, an eighth ram 6233, and an eighth cylinder 6234; the first folding groove 6232a is arranged on the tail rubber guide plate 6232, a pressing plate groove is further arranged on one side of the tail rubber guide plate 6232, the pressing plate groove is communicated with the first folding groove 6232a, and the plane where the first folding groove 6232a is located is crossed with the plane where the pressing plate groove is located. The eighth pressure head 6233 is connected with the tail rubber guide plate 6232, and the eighth pressure head 6233 and the tail rubber guide plate 6232 move relatively to each other, so as to clamp the tail rubber belt; the eighth cylinder 6234 is disposed on the tail rubber guide plate 6232, and the eighth cylinder 6234 is connected to the eighth ram 6233, and the eighth cylinder 6234 drives the eighth ram 6233 to move relative to the tail rubber guide plate 6232, so as to fold the end of the tailings in cooperation with the eighth ram 6238.

Further, the first folding groove 6232a is disposed at the bottom end of the tail rubber guide plate 6232, one side of the middle portion of the tail rubber guide plate 6232 is rotatably connected to the middle portion of the eighth pressure head 6233 through an eighth rotating shaft 6235, the eighth cylinder 6234 is connected to the top end of the eighth pressure head 6233, and the eighth cylinder 6234 drives the eighth pressure head 6233 to rotate around the eighth rotating shaft 6235, so that the eighth pressure head 6233 and the first folding groove 6232a move relatively.

In addition, an eighth elastic member 6236 is further disposed at one side of the tail rubber guide plate 6232, the eighth elastic member 6236 is located between the eighth rotating shaft 6235 and the first folding groove 6232a, and the eighth elastic member 6236 elastically presses the bottom end of the eighth pressing head 6233 away from the first folding groove 6232 a. And the eighth resilient member 6236 improves the structural stability of the eighth collet 6231 during use.

The eighth collet 6231 in this embodiment is coupled to the eighth base 51 through a fourth z-axis group. The fourth z-axis group drives the eighth chuck 6231 and the glue pushing assembly to move relatively, so that the efficiency of the structure for turning over the tail glue is improved.

In this embodiment, the glue-sucking component 621 includes a glue-sucking pressing block 6211, an eighth z-axis group 6212, and a first tail glue limiting ring 6213; wherein the glue absorption pressing block 6211 is used for absorbing tail glue; the eighth z-axis group 6212 is disposed on the eighth base 51, the eighth z-axis group 6212 is connected to the glue-sucking pressing block 6211, and the eighth z-axis group 6212 drives the glue-sucking pressing block 6211 and the corresponding gluing platform to move relatively. The first tail rubber limiting ring 6213 is arranged between the rubber suction pressing block 6211 and the active caching device 63 and used for guiding tail rubber, and the first tail rubber limiting ring 6213 is connected with the rubber suction pressing block 6211 through a first mounting shaft. The fourth z-axis group in the preferred embodiment is the eighth z-axis group 6212. The eighth chuck 6231 and the glue sucking pressing block 6211 in this embodiment are synchronously driven to move up and down through the eighth z-axis group 6212, and the structure is compact and the practicability is strong.

Further, a second tail rubber limiting ring 6214 is further arranged between the first tail rubber limiting ring 6213 and the active cache device 63, and the second tail rubber limiting ring 6214 is rotatably connected with the eighth base 51. Along with the eighth z-axis group 6212 drives the first tail rubber limiting ring 6213 to move up and down, so that the second tail rubber limiting ring 6214 and the first tail rubber limiting ring 6213 move relatively, the tail rubber material can be tensioned, and the stability of the structure in the using process is improved.

In the present invention, the tail rubber driving wheel 631 is detachably connected to the eighth base 51. The tail rubber driving wheels 631 of different sizes can be replaced by tail rubber materials of different lengths cached as required, and the structural practicability is strong.

In the present invention, the eighth base 51 is further connected to a counting sensor for detecting a rotation stroke of the tail rubber driving wheel 631.

According to the rubber cutting assembly, the rubber cutting assembly comprises a cutter 6221 and a cutter driving piece, the cutter 6221 is connected with the eighth base 51 through the cutter driving piece, and the cutter driving piece drives the cutter 6221 to move relative to the rubber pasting platform, so that the tail rubber material is cut and segmented. Further, the cutter driving piece pushes away gluey cylinder 6239 for the eighth, and cutter 6221 and eighth push away offset plate 6238 and all push away gluey cylinder 6239 synchro-driven through the eighth, promote the practicality of structure.

The cutter 6221 sets up in tail gum deflector 6232 below, is provided with first shear space 6232b on the tail gum deflector 6232, and first shear space 6232b is used for acceping cutter 6221, and compact structure, first shear space 6232b are convenient for acceping the tail sizing material of shearing, promote the stability of structure use process.

In the present invention, the rubberizing device 62 further comprises a rubberizing assembly 625, the rubberizing assembly 625 comprising a rubberizing top block 6251 and a rubberizing top block 6251; the rubberizing top block 6251 is arranged at the bottom end of the rubberizing pressing block 6211, and the rubberizing top block 6251 is used for supporting the tape material; the top rubber cylinder 6252 is connected with the eighth base 51, the top rubber cylinder 6252 is connected with the bottom end of the rubberizing top block 6251, the top rubber cylinder 6252 drives the rubberizing top block 6251 to move relative to the eighth chuck 6231, rubberizing efficiency of the rubberizing device 62 is improved, and the tape coiling material and the tail rubber material are pasted more stably.

The web material conveying structure in the present invention is explained with reference to fig. 18 to 20:

the coiled material conveying structure 7 comprises a seventh storage device 72 and a seventh conveying device 74; wherein the seventh stocker 74 is provided on the eighth base 71, and is configured to store the web material; the seventh conveyor 74 is provided between the seventh magazine 72 and the loading robot 73, the seventh conveyor 74 is connected to the eighth base 71, and the seventh conveyor 74 conveys the web material from the seventh magazine 72 to the loading robot 73.

The seventh conveyor 74 includes a seventh driving assembly 742 and a seventh guiding assembly 741, the seventh guiding assembly 741 includes a seventh conveying section 741a and a seventh detecting section 741b, and the seventh conveying section 741a is connected to an end of the seventh detecting section 741b away from the loading manipulator 73; the top end of the seventh detection section 741b is provided with a first buffer space, and the first buffer space is used for accommodating the unloaded tape.

A first buffer space is arranged on the seventh guide rail assembly 741, so that the feeding condition of the feeding manipulator 73 can be judged; when no material is accumulated in the first cache space, the feeding manipulator 73 successfully feeds the material; if the accumulated materials exist in the first cache space, the roll materials on the feeding manipulator 73 are not fed completely, and the roll materials are accumulated on the roll tape conveying mechanism; this structural design retrencies ingenious, can directly observe the material loading condition of material loading manipulator 73 in vain through first buffer memory space, and the structural practicability is strong.

The seventh rail assembly structure in this embodiment will be explained in detail:

in the present invention, the structure of the seventh rail assembly 741 in this embodiment will be explained in detail:

the seventh guiding rail assembly 741 of the present embodiment includes a seventh bottom plate 7411 and a seventh cover plate 7412, the seventh cover plate 7412 is fixed above the seventh bottom plate 7411, and the seventh cover plate 7412 is connected to the seventh conveying section 741a of the seventh bottom plate 7411. The length of the seventh cover plate 7412 is less than that of the seventh bottom plate 7411, a first buffer space is formed between the top surface of the seventh bottom plate 7411 and the side of the seventh cover plate 7412 as well as between the feeding manipulator 73, and the seventh guide rail assembly 741 is convenient to assemble in structure and strong in practicability.

Further, a detection through hole 7412a is further formed in the seventh guide rail component 741, the seventh conveying device 74 further comprises a winding correlation optical fiber 7413, and the winding correlation optical fiber 7413 is connected with the seventh guide rail component 741, so that the winding stroke on the feeding guide rail is detected, and the accuracy in the winding conveying process is improved.

The seventh transport apparatus 74 in this embodiment further includes a seventh air shear 744 and a stationary seventh air shear drive 745; the seventh air shear 744 is connected to the seventh rail assembly 741 via a seventh air shear drive 745, and the seventh air shear drive 745 drives the seventh air shear 744 for shearing. Set up seventh air shear 744 in seventh conveyor 74, promote the stability that the winding material was carried, compare in shearing the coil stock at the discharge end 731b of material loading manipulator 73 and shearing the coil stock at storage device's discharge end 731b, the transport of the material of being convenient for avoids the winding to shear the equipment that the fracture leads to and has reaction force, the lossy condition.

Further, an air shear limiting cavity 741d is disposed on the seventh guide rail assembly 741, the seventh air shear 744 is accommodated in the air shear limiting cavity 741d, and the seventh guide rail assembly 741 is connected to the air shear assembly through the seventh fixing plate 743. The seventh air shear 744 is accommodated in the air shear limiting cavity 741d, and two ends of the seventh guide rail assembly 741 limit two ends of the sheared tape material respectively, so that the stability of the tape material shearing operation is improved.

Be provided with the seventh fixed slot on the seventh fixed plate 743, the long limit place straight line of the long limit place straight line perpendicular to seventh guide rail assembly 741 of seventh fixed slot, and seventh fixed plate 743 passes through the adjustable connection of seventh fixed slot with seventh guide rail assembly 741 for the position that seventh air shear 744 sheared coiled strip material is adjustable, and the adaptation is in the coiled strip material of shearing multiple size, has promoted the practicality of structure in the seventh conveyor 74.

Further, in this embodiment, the seventh conveying device 74 further includes a cutter protection plate 746 and a cutter protection cylinder 747; wherein the cutter protection plate 746 is movably disposed above the seventh guide rail assembly 741, and the cutter protection plate 746 is correspondingly disposed at the first buffer space position; the cutter protection cylinder 747 is connected to the eighth base 71, the cutter protection cylinder 747 is connected to the cutter protection plate 746, and the cutter protection plate 746 is driven by the cutter protection cylinder 747 to move relative to the seventh guide rail assembly 741. The preferred initial position of the cutter guard plate 746 in this embodiment is located at one end of the seventh cover plate 7412 and above one end of the seventh base plate 7411.

The cutter protection cylinder 747 in this embodiment is used to drive the cutter protection plate 746 to press the coiled material, so as to improve the stability of the coiled material in the conveying process. The straight line of the motion track of the cutter protection plate 746 driven by the cutter protection cylinder 747 can be parallel to the seventh bottom plate 7411 and be seated on the plane; and the plane of the seventh bottom plate 7411 can be perpendicular to the plane, so that the structural adaptability is strong.

The structure of the seventh driving assembly 742 in this embodiment will be explained in detail:

a seventh driving assembly 742 is disposed between the seventh guiding rail assembly 741 and the seventh stocker 72, the seventh driving assembly 742 comprises a ratchet wheel 7421, a seventh driving motor, a seventh roller 7423 and a seventh roller driver 7424; the ratchet wheel 7421 is used for actively conveying the winding tape; the seventh driving motor is connected to the eighth base 71, and the seventh driving motor is connected to the ratchet 7421, and the seventh driving motor drives the ratchet 7421 to rotate. The seventh roller 7423 is movably arranged at the periphery of the ratchet wheel 7421, the coiling belt is arranged between the seventh roller 7423 and the ratchet wheel 7421 in a penetrating way, and the seventh roller 7423 is driven to roll the coiling belt for conveying; the seventh roller driver 7424 is connected to the eighth base 71, and the seventh roller driver 7424 is rotatably connected to the roller via a seventh rotating rod 7425. The seventh roller 7423 rotates relative to the ratchet 7421 to transfer the web material. The seventh driving assembly 742 is disposed between the seventh guiding rail assembly 741 and the seventh stocker 72, and drives the feeding device through two rollers, so that the feeding speed of the roll material is more stable.

The structure of the feeding robot in the present embodiment will be described in detail with reference to fig. 18, 23, and 24:

the feeding manipulator 73 is used for feeding material coils; it includes a seventh delivery rod assembly 731 and a seventh pushing assembly 732; a winding belt conveying channel is arranged in the seventh conveying rod assembly 731, and one end of the seventh conveying rod assembly 731 is rotatably connected with the eighth base 71; the seventh pushing assembly 732 is disposed on the eighth base 71, and the seventh pushing assembly 732 is movably connected to the seventh conveying rod assembly 731, and the seventh conveying driving member drives the seventh conveying rod assembly 731 to rotate.

Wherein, the seventh pushing assembly 732 comprises a fisheye push rod 7321 and a swing arm top cylinder 7322. The fisheye push rod 7321 is arranged below the seventh conveying rod assembly 731, and the fisheye push rod 7321 is rotatably connected with the seventh conveying rod assembly 731; the fisheye push rod 7321 is connected to the eighth base 71 through a swing arm top cylinder 7322, and the swing arm top cylinder 7322 drives the fisheye push rod 7321 to push the seventh conveying rod assembly 731, so that the seventh conveying rod assembly 731 rotates relative to the eighth base 71.

The eighth base 71 is provided with a swing arm bearing block 7323, and the seventh delivery rod assembly 731 is connected with the swing arm bearing block 7323 through a swing arm mounting shaft 7324; the seventh conveying rod assembly 731 includes a driving end 731a and a discharging end 731b, the driving end 731a is disposed at one end of the seventh conveying rod assembly 731, and the driving end 731a is rotatably connected to the swing arm mounting shaft 7324. The discharging end 731b is disposed at the other end of the seventh conveying rod assembly 731, and a plug 7312a is disposed at one end of the discharging end 731 b.

The driving end 731a is provided with a swing arm strip-shaped hole 7311a, a straight line of a long side of the swing arm strip-shaped hole 7311a is parallel to a straight line of a long side of the seventh conveying rod assembly 731, and the swing arm mounting shaft 7324 is movably inserted into the swing arm strip-shaped hole 7311 a.

When the plug 7312a of the seventh conveying rod assembly 731 is plugged with the butt-joint slot 131 on the tray 13, the swing arm mounting shaft 7324 contacts and limits the position of the side wall of one end of the swing arm strip-shaped hole 7311a far away from the plug 7312 a; when the seventh conveying rod assembly 731 receives materials, the swing arm top air cylinder 7322 drives the fisheye push rod 7321 to push the seventh conveying rod assembly 731, and under the action of the self-gravity of the seventh conveying rod assembly 731, the swing arm mounting shaft 7324 and the side wall of one end of the swing arm strip-shaped hole 7311a close to the plug-in connector 7312a are contacted and limited. When the seventh feeding rod assembly 731 outputs the winding material in the rotation process of the tray 13, the swing arm mounting shaft 7324 is movably connected to the swing arm strip hole 7311a as the winding diameter of the tray 13 increases. The structure is simple and skillful, the swing arm mounting shaft 7324 is movably connected with the swing arm strip-shaped holes 7311a, and the swing arm strip-shaped holes 7311a limit the movement range of the seventh conveying rod component 731, thus improving the stability in the use process; compared with a structure which directly drives feeding through a motor, the feeding device is not easy to damage.

In the present invention, the plurality of groups of the swing arm strip holes 7311a are arranged, and the arrangement direction of the plurality of swing arm strip holes 7311a is parallel to the straight line of the long side of the seventh conveying rod assembly 731. A plurality of swing arm strip holes 7311a are movably connected with the swing arm mounting shaft 7324, so that the conveying range of the seventh conveying rod assembly 731 can be adjusted.

In the utility model, a seventh adjusting sheet 7313 is arranged in the tape conveying channel, and the seventh adjusting sheet 7313 is adjustably connected with the top end of the seventh conveying rod assembly 731. The seventh adjustment sheet 7313 is used to adjust the height of the tape feed path; the practicality of structure is promoted.

The structure of the seventh transfer lever assembly 731 in this embodiment will be described in detail:

in the present invention, the seventh transportation rod assembly 731 includes a swing arm upper plate 7311, a swing arm lower plate 7312, and a swing arm connecting piece 7314; one side of the swing arm upper plate 7311 is rotatably connected to the eighth base 71; the swing arm lower plate 7312 is arranged at the bottom end of the swing arm upper plate 7311, a tape conveying channel is formed between the swing arm upper plate 7311 and the swing arm lower plate 7312, and the plug connector 7312a is arranged at one end of the swing arm lower plate 7312; the swing arm connecting pieces 7314 are provided in two sets, the two sets of swing arm connecting pieces 7314 are respectively provided on both sides of the swing arm lower plate 7312, and the swing arm connecting pieces 7314 connect the swing arm upper plate 7311 and the swing arm lower plate 7312.

Further, one end of each of the two groups of swing arm connecting pieces 7314, which is far away from the plug-in connector 7312a, is provided with a material guide plate 7314a, and the distance between the two groups of material guide plates 7314a, which is far away from one end of the plug-in connector 7312a, is gradually increased, so that the tape material is guided and conveyed conveniently, and the stability of the feeding manipulator 73 in the using process is improved.

The ends of the upper swing arm plate 7311 and the lower swing arm plate 7312 away from the plug 7312a are provided with a guiding inlet, which is convenient for the feeding and guiding of the feeding manipulator 73. Further, the swing arm upper plate 7311 in this embodiment is provided with a seventh curved surface, and the seventh curved surface improves the stability of the feeding manipulator 73 in bending the adhesive tape.

The tray rolling mechanism in the utility model is explained with reference to fig. 13-17:

a winding mechanism; it comprises a ninth conveying platform 92 and a ninth positioning device 93; the ninth conveying platform 92 is connected to the box 3 through a ninth base, the ninth conveying platform 92 includes a ninth x-axis group 922 and a ninth chuck assembly 921, the ninth chuck assembly 921 is connected to the ninth base through the ninth x-axis group 922, and the ninth x-axis group 922 drives the ninth chuck assembly 921 to move along the x-axis direction. The ninth positioning device 93 is disposed at the other side of the ninth conveying platform 92, and the ninth positioning device 93 is movably connected with the ninth chuck assembly 921, and the ninth positioning assembly is used for defining the position of the tray 13.

The tray winding mechanism in this embodiment further includes an auxiliary winding device 94, where the auxiliary winding device 94 includes a rubber rolling wheel 941, a rubber rolling rod assembly 942, and a rubber rolling driving assembly 943; wherein the rubber rolling wheel 941 is used for rolling the material tray 13 to obtain a coiled material; one end of the glue rolling rod assembly 942 is rotatably connected to the glue rolling wheel 941, and the other end of the glue rolling rod assembly 942 is rotatably connected to the ninth base through a ninth bearing seat. The rubber rolling drive assembly 943 is arranged on the ninth base, the rubber rolling drive assembly 943 is connected with the rubber rolling rod assembly 942, and the rubber rolling drive assembly 943 drives the rubber rolling rod assembly 942 to drive the rubber rolling wheel 941 to rotate around the ninth bearing seat.

Other structures of the tray winding mechanism are elaborated in detail:

the ninth positioning device 93 includes a ninth positioning roller 931 and a ninth positioning driving unit 932, the ninth positioning roller 931 is connected to the ninth base through the ninth positioning driving unit 932, and the ninth positioning driving unit 932 drives the ninth positioning roller 931 to move relative to the ninth chuck assembly 921, so as to clamp the tray 13.

Ninth location driving piece 932 in this embodiment includes ninth location extension rod 933, ninth slide rail and ninth cylinder, and ninth location extension rod 933 bottom rotates with ninth location gyro wheel 931 to be connected, and ninth location extension rod 933 top and ninth slide rail sliding connection, ninth cylinder set up on the ninth base, and the ninth cylinder is connected with ninth location extension rod 933, and ninth cylinder drive ninth location extension rod 933 slides along the ninth slide rail.

The auxiliary winding device 94 of the present invention is explained in detail:

further, the glue rolling driving assembly 943 includes a ninth positioning wheel 9431, a ninth top plate 9432 and a ninth top plate cylinder; wherein the ninth positioning wheel 9431 is connected to the glue bar assembly 942; the ninth top plate 9432 is arranged below the ninth positioning wheel 9431 and movably connected with the ninth positioning wheel 9431; the ninth head plate cylinder 9433 connects the ninth head plate 9432 to the ninth base via the ninth head plate cylinder 9433, and the ninth head plate cylinder 9433 drives the ninth head plate 9432 to move in conjunction with the ninth positioning wheel 9431.

When the ninth top plate 9432 is located at the bottom end of the ninth positioning wheel 9431, the rubber rolling wheel 941 presses the material tray 13 on the ninth chuck assembly 921 to roll rubber under its own weight, so as to improve the quality of the product wound on the material tray 13. When charging tray 13 finishes around rolling up, ninth roof cylinder 9433 drive ninth roof 9432 and drive ninth locating wheel 9431 and keep away from ninth chuck subassembly 921 to lift rubber rolling pole subassembly 942, this structural design retrencies ingeniously, and foot-rolling pole subassembly 942 drives rubber rolling wheel 941 and can adjust the roll extrusion each other along with the winding of taking material, and the structure practicality is strong.

Further, a ninth positioning wheel 9431 is disposed on the side of the glue rolling rod assembly 942 away from the ninth chuck assembly 921, a ninth ejecting plate cylinder 9433 is disposed on the side of the glue rolling rod assembly 942 away from the ninth chuck assembly 921, and a ninth ejecting plate 9432 is disposed on the side of the ninth positioning wheel close to the ninth chuck assembly 921. The structural design layout is simplified, and the practicability is high.

Further, the glue rolling driving assembly 943 further includes a ninth elastic member 9434, the ninth elastic member 9434 is disposed on a side of the glue rolling rod assembly 942 away from the ninth chuck assembly 921, one end of the ninth elastic member 9434 is connected to the glue rolling rod assembly 942, and the other end is connected to the ninth base, and the ninth elastic member 9434 drives the glue rolling rod assembly 942 to rotate toward the ninth chuck assembly 921; thereby make rubber coating wheel 941 and the charging tray 13 butt of the centre gripping on the ninth chuck subassembly 921, promote the finished product quality of charging tray batching.

In the present invention, the glue bar assembly 942 is provided with a plurality of ninth bearing attachment holes 9421 along the longitudinal direction, and the ninth glue bearing housing 9437 is adjustably connected to a plurality of second bearing attachment holes through a ninth bearing bar 9438. The rotating range of the glue rolling wheel 941 around the ninth glue rolling bearing seat 9437 is adjustable, and the practicability of the mechanism is improved.

In the utility model, the auxiliary winding device 94 further comprises an opening plate 9435 and a disc opening cylinder 9436; the expanding plate 9435 is arranged between the ninth chuck assembly 921 and the glue rolling wheel 941 and is used for expanding the material tray 13 clamped on the ninth chuck assembly 921; the bottom end of the distraction plate in this embodiment is provided with a distraction guide portion, and the cross-sectional width of the distraction guide portion gradually decreases near one end of the ninth chuck assembly 921.

The disc supporting cylinder 9436 is disposed on the ninth base and connected to an end of the opening plate 9435 away from the ninth chuck assembly 921, and the disc supporting cylinder 9436 drives the opening plate 9435 to move relative to the ninth chuck assembly. Be provided with and strut board 9435 and strut charging tray 13, the rolling wheel of being convenient for pushes down the rubber coating, promotes the precision in the supplementary coiling mechanism 94 use.

The ninth chuck assembly structure in this embodiment will be described in detail:

the ninth chuck assembly 921 includes a ninth support base 9211, a ninth chuck 9212, a ninth driving motor 9215, a ninth push plate 9213, and a ninth push plate cylinder 9214; wherein the ninth supporting seat 9211 is connected with the ninth x-axis group 922; the ninth chuck 9212 is rotatably connected with the ninth supporting seat 9211, and the ninth chuck 9212 is used for clamping the tray 13; the ninth push plate 9213 is arranged on one side of the ninth chuck 9212 and used for pushing the material tray 13; the ninth push plate cylinder 9214 is provided on the ninth support seat 9211, and the ninth push plate cylinder 9214 is connected to the ninth push plate 9213. The ninth driving motor 9215 is connected to the ninth supporting seat 9211, the ninth driving motor 9215 is connected to the ninth chuck 9212 through a belt, and the ninth driving motor 9215 drives the ninth chuck 9212 to rotate and wind.

The ninth push plate cylinder 9214 drives the ninth push plate 9213 to push the material tray 13, and the straight line of the long edge of the ninth x-axis group 922 where the movement locus of the ninth push plate 9213 is located is parallel, so that the coiled material tray 13 can be output conveniently, and the structural practicability is high.

The tray feeding mechanism 1 in this embodiment will be described in detail with reference to fig. 3 to 8:

the tray feeding mechanism 1 in this embodiment includes a first connecting frame 11, a first bin 12, a first rotating device 19, a first telescoping device 13, and a first positioning device 17. Wherein, two sides of the first connecting frame 11 are connected with the inner wall of the box 3 in a sliding way. The handle is further arranged at one end of the first connecting frame body 11, so that the first connecting frame body 11 can be pulled conveniently. First workbin 12 is used for placing the charging tray, and first workbin 12 sets up in first connection framework 11, and first workbin 12 tops are provided with first feed inlet, and the both ends of first workbin 12 and first connection framework 11 all are provided with dodges the breach of dodging peg graft pole part 23.

In the use process of the charging tray feeding mechanism 1 in the embodiment, after the insertion rod part 23 is inserted into the charging tray, the charging tray can be driven upwards by the driving device, and the insertion rod part 23 drives the charging tray to be separated from the first charging tray 12; then the connecting frame is matched with and slides out of the box body 3, so that the material trays can be conveyed downwards, and the output first material box 12 can load the next batch of empty material trays; this structural design simplifies, and vertical material receiving machine cooperates the feed structure of drawer type charging tray, has further saved the occupation space of equipment, and the structural practicality is strong.

Preferably, the insertion rod part 23 in this embodiment also comprises a bin down position on the movement trajectory, which is located above the first loading position. When the plugging rod component 23 is positioned at a first material loading position, the plugging rod component 23 is plugged with the material tray; when the inserting rod component 23 moves to the material discharging position of the material box, the inserting rod component 23 drives the material plate to be separated from the first material box 12, and the material plate is conveniently conveyed to the winding mechanism 5.

The tray feeding mechanism 1 further comprises a first rotating device 19, the first rotating device 19 is fixedly connected with the first connecting frame 11, the first rotating device 19 is connected with the first material box 12, and the first rotating device 19 drives the first material box 12 to rotate so as to adjust the direction of the first feeding hole. Through setting up the output position of 19 adjustment charging trays of first rotating device, further save the movement stroke of insertion rod part 23, shortened insertion rod part 23 and removed the workbin from first material loading level and descend the distance between the material level, promoted the compactedness and the practicality of structure, further saved charging tray batch transport structure's compactedness, save the charging tray in transportation process equipment usage space.

When the material tray is discharged, the first connecting frame 11 drives the first material tray 12 to be inserted into the insertion rod component 23, and then the insertion rod component 23 is driven by the driving device to move from the first material loading position to the material tray discharging position. When the insertion rod component 23 is located at the first loading position, the insertion rod component 23 is inserted into the material tray, and the central axes of the material tray and the insertion rod component 23 are located below the central axes of the first material box 12 and the first rotating device 19. And the central axis of the tray and the plugging rod member 23 in this embodiment is located 2.5 cm below the central axis of the first magazine 12 and the first rotating means 19.

When the inserting rod component 23 moves to a bin discharging position, the rotation center of the first rotating device 19, the first bin 12, the material tray and the center of the inserting rod component 23 are all on the same axis; i.e. the first loading level in this embodiment is moved to the bin loading level preferably by a distance of 2.5 cm. When the central axis of charging tray and peg graft pole part 23 and the central axis of first workbin 12 and first rotary device 19 are located the collinear, first rotary device 19 drive first workbin 12 and rotate to avoid producing wearing and tearing between charging tray and the first workbin 12, structural design is exquisite, and the practicality is strong.

In the present invention, the first rotating device 19 includes a first socket 191 and a first rotating cylinder 193; the first socket 191 comprises a plurality of rotary plugs 192, and the rotary plugs 192 are arranged in a circular array around the center of the first material box 12 along the projection of the plane where the side wall of the first material box 12 is located; the first rotary cylinder 193 is connected to the first connection frame 11, the first rotary cylinder 193 is connected to the first socket 191, and the first rotary cylinder 193 rotates the first rotary plug 192. Be provided with a plurality of plugs and peg graft with first workbin 12, promote the stability of structural connection, and avoid a single center pin drive to rotate the error that produces, the structural practicality is strong.

The structure of the first telescopic device 13 in the utility model is explained:

the tray feeding mechanism 1 further comprises a first telescopic device 13, the first telescopic device 13 is fixedly connected with the first connecting frame 11, the output end of the first telescopic device 13 is connected with a first rotating device 19, and the first telescopic device 13 drives the first rotating device 19 to move relative to the first material box 12. This structural design is exquisite, through the relative first workbin 12 motion of first rotating device 19 of first telescoping device 13 drive for but split between first workbin 12 and the first rotating device 19 avoids first workbin 12 to cause the loss to first rotating device 19 when bearing the charging tray, promotes the stability in the structure use.

In this embodiment, the first telescopic device 13 includes a first telescopic cylinder 131 and a guide post; the first telescopic cylinder 131 is connected with the first connecting frame body 11 through a third baffle 16, and the output end of the first telescopic cylinder 131 is connected with the first rotating device 19; one end of the guide post is connected with the first rotating device 19, the other end of the guide post penetrates through the third baffle 16, and the guide post is connected with the third baffle 16 in a sliding mode. Be provided with first telescopic cylinder 131 and drive first rotating device 19 and slide relatively first workbin 12, the guide post promotes the gliding stability of first rotating assembly, avoids the stability of first rotating device 19 horizontal transport direction mesostructure.

In the present invention, the first hopper 12 is detachably connected to the first connection frame 11. The first material box 12 and the first connecting frame 11 can be detached, so that the hole material plate can be conveniently loaded, and the practicability of the structure is improved.

Furthermore, a first rotating seat 121 and a second rotating seat 122 are oppositely arranged at two ends of the first material box 12; a first baffle 14, a second baffle 15 and a third baffle 16 are arranged in the first connecting frame 11; the first baffle plate 14 is arranged at one end of the first material box 12 close to the first rotating device 19, a first slide way 141 with an open top end is vertically arranged on the first baffle plate 14, and the first rotating seat 121 is movably connected with the first slide way 141; the second baffle 15 is arranged at the other end of the first material box 12, the second baffle 15 is vertically arranged on one side of the second baffle 15, a second slide way 151 is arranged on the second baffle 15, the second slide way 151 is opposite to the first slide way 141, and the second rotating seat 122 is movably connected with the second slide way 151.

The top ends of the first slide rail 141 and the second slide rail 151 in this embodiment are both provided with openings, and the two connecting seats slide along the vertical direction with the first slide rail 141 and the second slide rail respectively, so that the first connecting frame body 11 and the first material box 12 are detached, and loading of the material tray is facilitated.

The structure of the first positioning device 17 in the present invention is explained:

the side wall of the first feed box 12 in the utility model is provided with a positioning groove 123, and the tray feeding mechanism 1 further comprises a first positioning device 17 for limiting the position of the first feed box 12. The first positioning device 17 comprises a first positioning block 171 and a first positioning driving member 172; wherein the first positioning block 171 is movably connected with the positioning groove 123; the first positioning driving member 172 is disposed on the first connecting frame 11, and the first positioning driving member 172 is connected to the first positioning block 171, and the first positioning driving member 172 drives the first positioning block 171 to be inserted into the positioning groove 123, so as to define the position of the first material box 12 and improve the stability of the first material box 12 in the first connecting frame 11.

Further, the side wall of the first magazine 12 in this embodiment is provided with a first guiding notch 12a, and the first guiding notch 12a is used for limiting the moving direction of the inserting rod part 23.

The magnetic lock 18 is further disposed at one end of the first connection frame 11, the second magnetic member is disposed at an end of the first material box 12, preferably, the magnetic lock 18 in this embodiment is connected to the first baffle 14, the first connection seat 22 is disposed with a magnetic area corresponding to the position of the magnetic lock 18, and when the first connection frame 11 and the first material box are assembled in place, the magnetic lock 18 magnetically adsorbs the first material box 12.

The transfer mechanism 2 in the present invention will be described in detail with reference to fig. 9 to 12:

the transfer mechanism 2 in the utility model comprises an insertion rod component 23, a driving device and a first pushing device 24; the plugging rod component 23 is used for plugging a material tray, the driving device and the plugging rod component 23, and the driving device drives the plugging rod component 23 to convey the material tray among the winding mechanism 5, the material tray feeding mechanism 1 and the discharging mechanism 4. The first pushing device 24 is arranged on one side of the insertion rod part 23 and used for pushing the tray along the straight line of the long edge of the insertion rod part 23.

In the present invention, the driving device includes a first connecting seat 22 and a first z-axis group 21; wherein one end of the insertion rod component 23 is connected with the first connecting seat 22; the first connecting seat 22 of the first z-axis group 21 is connected, the first z-axis group 21 drives the insertion rod component 23 to move up and down, the insertion rod component 23 comprises a first material loading position, a material tray rolling position and a full material unloading position on a motion track, and the first material loading position, the material tray rolling position and the full material unloading position are all located on the same straight line.

Further, the insertion rod part 23 includes a first empty tray hanging rod 231 and a first full tray hanging rod 232; first empty tray peg 231 is with the charging tray from first material loading level conveyer belt charging tray rolling position, and first full tray peg 232 sets up in first empty tray peg 231 below, and first full tray peg 232 is from the charging tray rolling position to full material unloading level. Be provided with first empty dish peg 231 and first full dish peg 232 respectively, the integrated form of being convenient for is received the material machine and is satisfied the unloading in batches of charging tray, has retrencied the transmission step in big batch charging tray winding operation, has promoted the whole production efficiency who carries the operation of rolling machine.

Further, when the first empty tray hanging rod 231 is located at the first material loading position, the first full tray hanging rod 232 is located at the material tray rolling position; when the first empty tray hanging rod 231 is located at the tray rolling position, the first full tray hanging rod 232 is located at the full-tray loading and unloading position. First empty dish peg 231 and first full dish peg 232 carry out the operation of carrying the charging tray in step, have further saved the time that transfer mechanism 2 carried the charging tray, and the structure practicality is strong.

Further, the first z-axis group 21 includes a first vertical plate 211, a first sliding rail 214 and a first driving element 215; the first vertical plate 211 is vertically arranged; the first slide rail 214 is vertically arranged at the side edge of the first vertical plate 211, and the first connecting seat 22 is slidably connected with the first vertical plate 211; the first driving member 215 is disposed on the first vertical plate 211 and connected to the first connecting seat 22, and the first driving member 215 drives the first connecting seat 22 to slide along the first sliding rail 214. The first drive member 215 in the preferred embodiment is a first drive linear cylinder.

Further, a first rubber gasket 212 is disposed at the top end of the first vertical plate 211, and the first rubber gasket 212 is located above the first connecting seat 22. The first high-strength rubber washer 212 is used to define the position of the first connecting seat 22 on the top end of the first sliding rail 214, and to improve the stability of the transfer mechanism 2 during use.

The first bottom plate is further provided with a second high-strength rubber gasket 213, and the second high-strength rubber gasket 213 is located below the first connecting seat 22. The second high-strength rubber washer 213 is used to define the position of the first connector 22 at the bottom end of the first slide rail 214.

The first connecting seat 22 is also provided with a first photoelectric sensor 216 at a side thereof. The preferred first photosensors 216 are arranged in groups. And a plurality of first photoelectric sensors are connected with the box body 3, and preferably, the positions of the plurality of first photoelectric sensors 216 correspond to the positions of the first feeding position, the first material tray rolling position and the first full-material discharging position. First connecting seat 22 side fixedly connected with responds to piece 217, works as and responds to piece 217 and moves along with first connecting seat 22, and first photoelectric sensor 216 is used for detecting the motion position of responding to piece 217, promotes the accurate nature of transfer mechanism 2 dispatch charging tray. The first photoelectric sensor 216 is used for detecting whether the plug rod part 23 is conveyed to a working position, so that the stability of the structure in the using process is improved.

The structure of the first pushing device 24 in the present invention is explained:

the first pushing device 24 comprises a first pushing plate 241 and a first x-axis set 242; the first push plate 241 is arranged on one side of the tray rolling position, and the first push plate 241 is used for abutting against the tray; the first x-axis group 242 is arranged on one side of the tray rolling position, the first push plate 241 is connected with the first x-axis group 242, a straight line where a long edge of the first x-axis group 242 is located is parallel to a straight line where a long edge of the insertion rod part 23 is located, and the first x-axis group 242 drives the first push plate 241 to move along the x-axis direction.

Further, a first avoiding hole 241a is formed in the first pushing plate 241, an inserting opening is formed in the top end of the first avoiding hole 241a, the first avoiding through hole is inserted into the inserting rod component 23, the contact area between the first pushing plate 241 and the material tray is increased, and therefore the stability of pushing the material tray is improved.

In addition, a second avoiding notch 221 is further formed on the first connecting seat 22 close to the first pushing device 24,

the second avoiding gap 221 is located between the first empty tray hanging rod 231 and the first full tray hanging rod 232, and the second avoiding gap 221 facilitates the first pushing plate 241 to return, so that the first pushing plate 241 can push the first empty tray hanging rod 231 located at the tray rolling position.

The structure of the case 3 in this embodiment will be described in detail with reference to fig. 1:

the inner wall of the box body 3 is also provided with a material preparation area, and the material preparation area is positioned below the material discharging area; integrated receipts material machine still includes the drawer 31 of prepareeing material, and the drawer 31 of prepareeing material sets up in the region of prepareeing material, and the drawer 31 of prepareeing material is used for placing reserve material, and the drawer 31 of prepareeing material sets up in unloading mechanism below, and the drawer 31 of prepareeing material and 3 one end sliding connection of box.

In the utility model, the universal wheel 32 and the brake component connected with the universal wheel 32 are arranged at the bottom end of the box body 3, so that the integrated material collecting machine is convenient to use, and the structure is strong in practicability.

A file box 33 is arranged on the side wall of the box body 3, and the file box 33 is used for storing a notebook; in the using process, the top cover of the integrated material receiving machine can be used as a workbench, and the file box 33 is used for storing production notes. The whole structure of the device is simplified, and the compactness and the practicability of the structure of the integrated winding machine are improved.

With reference to fig. 25, the structure of the blanking mechanism 4 in this embodiment is described in detail:

the blanking mechanism 4 in this embodiment includes a second connection frame 41 and a second hopper 42. Wherein, the two sides of the second connecting frame 41 are connected with the inner wall of the box 3 in a sliding way. One end of the second connecting frame 41 is further provided with a handle, which facilitates the drawing of the second connecting frame 41. The second feed box 42 is used for placing a material tray, the second feed box 42 is arranged in the second connecting frame body 41, a second feed opening is formed in the top end of the second feed box 42, and second avoiding notches for avoiding the insertion rod components are formed in the two ends of the second feed box 42 and the two ends of the second connecting frame body 41.

The working principle of the integrated material receiving machine in the embodiment is explained as follows:

and the material tray feeding mechanism conveys the empty material tray to the transfer mechanism for feeding.

1. The inserting rod part 131 of the transfer mechanism 2 is positioned at a first material loading position; the first empty tray hanging lever 231 in this embodiment is located in the empty tray region. A first connecting frame body 11 in the material tray feeding mechanism 1 drives a first material box 12 for containing an empty material tray group to slide to an empty tray area of the box 11. So that the first material box 12 is inserted into the first empty tray hanging rod 231 of the transfer mechanism 2.

2. The first z-axis group in the transfer mechanism 2 drives the first empty tray hanging rod 231 to move upwards, so that the tray is raised, the plugging rod part 23 moves from the first loading position to the tray turning position, and the tray is separated from the first material box.

3. The first telescopic device 13 drives the first rotating device 19 to be plugged into the first magazine end 12. After plugging, the first rotating device 19 rotates the first magazine 12, thereby adjusting the discharge direction of the empty magazine. Preferably, the first rotating device 19 in the embodiment drives the first material box to rotate 180 degrees, so that the material box can discharge materials from the lower part, the structure is compact, the floor area of equipment is reduced, and the practicability is high.

And secondly, the transfer mechanism conveys the material tray from the material tray feeding mechanism to the winding mechanism.

1. The first z-axis group 21 in the transfer mechanism 2 drives the plugging rod member 23 to move from the first loading position to the tray rolling position.

When the second avoiding notch 221 of the first connecting seat 22 corresponds to the first push plate 241 of the first pushing device 24 during the transferring process of the inserting rod component 23, the first push plate 241 is driven by the first x-axis group 242 to be located between the first empty tray hanging rod 231 and the first full tray hanging rod 232.

When the plugging rod member 23 moves to the tray rolling position, the first empty tray hanging rod 231 is accommodated in the first avoiding hole 241a of the first push plate 241, so that the stability of pushing the tray by the push plate is improved.

The ninth x-axis group 922 in the winding mechanism 9 drives the ninth chuck assembly 921 to slide along the x-axis, so that the ninth chuck 9212 in the ninth chuck assembly 921 is inserted into the first empty tray hanging rod 231.

The transfer mechanism 2 drives the first push plate 241 to push the tray along the X-axis direction through the first X-axis group 242, and the tray is conveyed from the first empty tray hanging rod 231 to the ninth chuck 9212, so that the loading of the empty tray is completed.

And thirdly, the coil feeding mechanism 5 conveys the coil to the winding mechanism 9, and the coil is formed by adhering a coil material and a tail rubber material.

1. The web conveying structure 7 conveys the web.

First, the seventh driving unit 742 of the seventh transport device 74 of the tape transport mechanism 7 drives the tape to rotate in the direction of the loading robot 73. The tape is arranged between the seventh roller 7423 and the ratchet wheel 7421 in a penetrating way, and the seventh roller 7423 can abut against and press the tape on the ratchet wheel 7421; the seventh driving motor 7422 drives the ratchet wheel 7421 to rotate, so that the seventh roller 7423 rotates relative to the ratchet wheel 7421 to transfer the web material.

Second, the seventh guide rail assembly 741 detects the guide material. The tape penetrates through the seventh guide rail assembly 741; and the stroke of the winding on the winding correlation optical fiber detection seventh guide rail component 741 improves the accuracy of the winding conveying process.

2. The feeding robot 73 feeds the coil. When the plug 7312a of the seventh feeding rod assembly 731 is plugged into the docking slot 131 on the tray 13, the swing arm mounting shaft 7324 and the swing arm strip-shaped hole 7311a are in contact with the side wall of the end far from the plug 7312a for limiting. The fisheye push rod 7321 and the buffer member 7327 of the seventh pushing assembly 732 support and limit the bottom end of the seventh conveying rod assembly 731.

When the plug 7312a on the loading manipulator 73 is not aligned with the docking slot 131 on the tray 13. The seventh conveying assembly 472 still drives the coiled material to be loaded, and at this time, the material is stacked in the first buffer space under the limitation of the side wall of the tray 12 and the seventh guide rail assembly 741; the user can visual detection take the material loading condition of material. When the plug 7312a of the seventh transportation rod assembly 731 is plugged into the docking slot 131 of the tray 13 with the rotation of the tray 13, the tape material stacked in the first buffer space is output from the loading manipulator 73, and there is no material accumulation in the first buffer space.

3. The tail rubber conveying structure 6 conveys tail rubber.

First, the tail rubber material is placed by the rubber placing tray device 82, and the head of the tail rubber material is adsorbed by the rubber absorbing component 621 in the rubber pasting device 62.

Then, the eighth z-axis group 6212 in the glue suction assembly 621 drives the glue suction pressing block 6211 to press down, so as to attach the tail glue to the tape material. The eighth z-axis group 86 drives the eighth sliding block to drive the glue sucking pressing block 6211 to move towards the gluing jacking block 6281 by the eighth z-axis cylinder.

Secondly, inhale gluey subassembly 621 and deliver to the position, inhale gluey briquetting 6211 and be located rubberizing kicking block 6281 top, top gluey cylinder 6252 drive rubberizing kicking block 6251 for inhale gluey briquetting 6211 motion to paste the position of pasting of tail sizing material in the volume area material, promote the stability of tail sizing material loading.

Then, the glue ejecting cylinder 88 drives the glue applying ejector block 6281 to reset, and the eighth z-axis group 6212 drives the glue sucking press block 6211 to move away from the coiled material. And conveying the tail rubber material along with the coiled belt material.

4. The web conveying structure 7 cuts the web.

Cutting the coil stock after the coiling of the material tray is finished; before shearing the material, the cutter protection cylinder 747 drives the cutter protection plate 746 to press the winding material at the first buffer space position, so as to avoid the winding material after shearing to be separated.

Then, seventh air shear 744 shears the web with seventh air shear drive 745; seventh air shear 744 is accommodated in air shear limiting cavity 741d, and the two ends of seventh guide rail component 741 are respectively limiting the two ends of the sheared tape material, so that the stability of the tape material shearing operation is improved.

5. The tail rubber conveying structure 6 shears the tail rubber.

First, the tail rubber compound is conveyed to a set length, then the cutter 6221 in the rubber compound cutting assembly 622 and the eighth rubber compound pushing plate 6238841 move upwards synchronously, and the cutter 6221 cuts and segments the tail rubber compound.

The eighth glue pushing cylinder 842 drives the eighth glue pushing plate 6238841 to move relative to the first folding groove 831a, so that the head of the tail glue is conveyed into the first chuck 6231; the eighth cylinder 833 drives the eighth pressing head 832 to press downwards, and the eighth pressing head 832 and the first folding groove 831a clamp the folded end of the tail rubber material. So that the tail rubber end part forms a turnover end part.

Meanwhile, a glue suction pressing block 6211 in the glue suction assembly 621 adsorbs and fixes the tail glue material left after shearing, and the second tail glue limiting ring 6214 move relatively, so that the adhesive tape is tensioned, and the stability of adsorbing and grabbing the tail glue material by the gluing device 62 is improved; the stability of being convenient for direction tail sizing material is carried avoids the tail to glue the rupture, and the structure practicality is strong.

Fourthly, the winding mechanism 9 carries out rotation winding operation.

1. The ninth chuck assembly 921 fixes the tray 13. First, the tray 13 is inserted into the ninth chuck 9212 of the ninth chuck assembly 921, and the ninth support 9211 is repositioned along the ninth x-axis group 922.

Then, the ninth positioning device 93 determines the receiving position of the tray 13; the ninth positioning roller 931 slides under the ninth positioning driving member 932 to the side of the tray 13 away from the ninth chuck assembly 921, and corresponds to the center of the tray 13; the ninth x-axis group 922 drives the ninth chuck assembly 921 to slide along the x-axis such that the ninth positioning roller 931 interfaces with the end of the ninth collet 9212. The two sides of the material tray 13 are limited by the ninth chuck assembly 921 and the ninth positioning roller 931 respectively, so that the stability of the material tray 13 in the winding process is improved.

2. The ninth chuck assembly 921 rotates for winding.

First, the ninth driving motor 9251 of the ninth supporting seat 9211 drives the ninth chuck 9212 to drive the tray 13 to rotate.

Next, a ninth optical fiber detector is further provided on the ninth support base 9211. The ninth fiber detector is preferably disposed below the ninth collet 9212, and the ninth ejector 9215 is disposed above the ninth collet 9212.

When the ninth optical fiber detector detects the rotating position of the tray 13, the inserting groove is rotated to correspond to the feeding manipulator 73 when the tray 13, the operation of feeding the coil materials is conveniently carried out on the tray 13, and the practicability of the tray winding mechanism is improved. Then, the ninth chuck 9212 drives the tray 13 to rotate to wind after the coil stock is fed.

3. And the auxiliary positioning assembly is used for carrying out pressing operation.

The reeled material tray 13 drives the glue rolling rod assembly 942 to rotate towards the direction close to the ninth chuck assembly 921 through the ninth elastic member 9434; so that the rubber rolling wheel 941 abuts against the material tray 13 clamped on the ninth chuck assembly 921 and rotates relative to the material tray 13. So that the tail rubber material is more tightly pasted and wound, and the quality of finished products rolled by the material tray 13 is improved.

4. The pressing operation is finished and the auxiliary winding device 94 and the ninth positioning device 93 are reset. And the rubber rolling wheel 941 is reset. The ninth top plate 9432 is located at the bottom end of the ninth positioning wheel 9431, and when the rubber rolling wheel 941 presses the rubber rolling with the material tray 13 on the ninth chuck assembly 921 under its own weight, the product quality of the material tray 13 wound around the roll is improved. When charging tray 13 finishes around rolling up, ninth roof cylinder 9433 drive ninth roof 9432 and drive ninth locating wheel 9431 and keep away from ninth chuck subassembly 921 to lift rubber rolling pole subassembly 942, this structural design retrencies ingeniously, and foot-rolling pole subassembly 942 drives rubber rolling wheel 941 and can adjust the roll extrusion each other along with the winding of taking material, and the structure practicality is strong.

Fifthly, the winding mechanism 9 finishes winding and conveys full materials to the transfer mechanism 2.

1. The third manipulator 73 is reset.

After the tape is rolled, the swing arm top-lifting cylinder 7322 drives the fisheye push rod 7321 to push the seventh conveying rod assembly 731 upwards, and under the action of the self-gravity of the seventh conveying rod assembly 731, the swing arm mounting shaft 7324 and the side wall of one end of the swing arm strip-shaped hole 7311a close to the plug-in connector 7312a are contacted and limited. Accordingly, the seventh conveyance bar assembly 731 is stored, and the stability of the standby state structure of the loading robot 73 is improved.

2. The first z-axis group 21 in the transfer mechanism 2 drives the first full-tray hanging rod 232 in the plugging rod component 23 to move to the tray rolling position.

When the first z-axis group 21 drives the plugging rod component 23 to move upward, and the second avoiding notch 221 on the first connection seat 22 corresponds to the first pushing plate 241 on the first pushing device 24, the first pushing plate 241 moves to a side of the first connection seat 22 away from the plugging rod component 22 under the driving of the first x-axis group 242, so as to avoid the position.

3. The ninth x-axis group 922 in the winding mechanism 9 drives the ninth chuck assembly 921 to slide along the x-axis, so that the ninth chuck 9212 in the ninth chuck assembly 921 is inserted into the first empty tray hanging rod 231.

The ninth chuck assembly 921 drives the ninth pusher 9213 to push the full tray along the ninth chuck 9212 by the ninth pusher cylinder 9214, and the full tray is conveyed from the ninth chuck 9212 to the first full tray hanging rod 232, so that the full tray feeding is completed to the transfer mechanism 2.

Sixthly, the transfer mechanism 2 conveys the full materials to the blanking mechanism 4 for blanking.

1. The transfer mechanism 2 drives the first full tray flight 232 in the peg member 22 from the winding area to the finishing area.

In the transferring process of the insertion rod component 23, when the first z-axis group 21 drives the first empty tray hanging rod 231 and the first full tray hanging rod 232 in the insertion rod component 23 to synchronously convey; when the first full tray hanging rod 232 is located at the tray rolling position, the first empty tray hanging rod 231 is located at the first feeding position; when the first full tray hanging rod 232 is located at the full material feeding position, the first empty tray hanging rod 231 is located at the material tray rolling position. First empty dish peg 231 and first full dish peg 232 carry out the operation of carrying the charging tray in step, have further saved the time that transfer mechanism 2 carried the charging tray, and the structure practicality is strong.

2. The first full-tray hanging rod 232 drives the full material to move to the full-material discharging position, and at the moment, the first full-tray hanging rod 232 drives the full material to be contained in the second material box 42 of the discharging mechanism 4; then the second connecting frame 41 is pulled, and the second connecting frame 41 drives the second material box 42 containing the full material disc group to slide out to the finished product area of the box body 3. So that the second material box 42 is separated from the first full-plate hanging rod 232 in the transfer mechanism 2, and the blanking of the full-material finished product is completed.

Thus, the winding process of the integrated collecting machine of the preferred embodiment is completed.

In summary, although the present invention has been described with reference to the preferred embodiments, the above-described preferred embodiments are not intended to limit the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, therefore, the scope of the present invention shall be determined by the appended claims.

Claims (10)

1. A tail rubber conveying structure, which is used for attaching tail rubber to a rolling belt material; it is characterized by comprising the following steps:

an eighth base, wherein the first base is provided with a plurality of grooves,

the rubber plate placing device is arranged on the eighth base and used for placing a tail rubber plate;

the rubberizing device is connected with the eighth base, is positioned on one side of the rubber placing disc device and is used for conveying the tail rubber material to the corresponding rubberizing platform; and

the active buffer device is arranged between the rubber placing disc device and the rubber pasting device and drives the tail rubber to be conveyed from the rubber placing disc device to the rubber pasting device;

wherein, the active cache device comprises:

the tail rubber driving wheel is rotationally connected with the eighth base; and

the eighth rotating motor, with eighth base fixed connection, the eighth rotating motor through the eighth hold-in range with the tail gum action wheel transmission is connected, the eighth rotating motor drive the tail gum action wheel rotates.

2. The tail rubber conveying structure according to claim 1, wherein the rubber coating device comprises:

the glue sucking assembly is used for clamping the tail glue stock and attaching the tail glue stock to the corresponding gluing platform;

the glue cutting assembly is arranged at one end, far away from the active caching device, of the glue sucking assembly, and the glue cutting assembly and the eighth base are used for cutting tail glue materials;

the turnover assembly is arranged on one side, away from the glue sucking assembly, of the glue cutting assembly, and the turnover assembly is used for turning over the sheared tail glue.

3. The tail rubber conveying structure according to claim 2, wherein the turnover assembly comprises:

an eighth chuck for clamping the tail rubber material, wherein a first folding groove is arranged on the eighth chuck,

the eighth rubber pushing plate is arranged below the eighth chuck and corresponds to the first turnover groove in position; and

the eighth glue pushing cylinder is connected with the eighth base, and drives the eighth glue pushing plate to be movably connected with the first turnover groove, so that the tail glue is turned over.

4. The tail rubber conveying structure according to claim 3, wherein the eighth chuck includes:

the first folding groove is arranged on the tail rubber guide plate, one side of the tail rubber guide plate is also provided with a pressing plate groove, the pressing plate groove is communicated with the first folding groove, the plane of the first folding groove is crossed with the plane of the pressing plate groove,

the eighth pressure head is connected with the tail rubber guide plate, and the eighth pressure head and the tail rubber guide plate move relatively to clamp the tail rubber belt; and

the eighth cylinder sets up on the tail rubber deflector, just the eighth cylinder with the eighth pressure head is connected, the eighth cylinder drive the eighth pressure head is relative the motion of tail rubber deflector.

5. The tail rubber conveying structure according to claim 4, wherein the first folding groove is formed in the bottom end of the tail rubber guide plate, one side of the middle of the tail rubber guide plate is rotatably connected with the middle of the eighth pressing head through an eighth rotating shaft, the eighth air cylinder is connected with the top end of the eighth pressing head, and the eighth air cylinder drives the eighth pressing head to rotate around the eighth rotating shaft, so that the eighth pressing head and the first folding groove move relatively.

6. The tail rubber conveying structure of claim 5, wherein an eighth elastic member is further disposed on one side of the tail rubber guide plate, the eighth elastic member is located between the eighth rotating shaft and the first folding groove, and the eighth elastic member elastically presses the bottom end of the eighth pressing head to be away from the first folding groove.

7. A tail rubber conveying structure according to claim 2, wherein the rubber suction assembly comprises:

the glue absorption pressing block is used for absorbing tail glue;

the eighth z-axis group is arranged on the eighth base and connected with the glue sucking pressing block, and the eighth z-axis group drives the glue sucking pressing block and the corresponding gluing platform to move relatively; and

the first tail rubber limiting ring is arranged between the rubber suction pressing block and the active caching device and used for guiding tail rubber materials, and the first tail rubber limiting ring is connected with the rubber suction pressing block through a first mounting shaft.

8. The tail rubber conveying structure according to claim 6, wherein the tail rubber driving wheel is detachably connected with the eighth base.

9. The tail rubber conveying structure according to claim 2, wherein the rubber cutting assembly comprises a cutter and a cutter driving member, the cutter is connected with the eighth base through the cutter driving member, and the cutter driving member drives the cutter to move relative to the rubberizing platform.

10. The tail rubber conveying structure according to claim 3, wherein the rubber coating device further comprises a rubber coating component, and the rubber coating component comprises:

the rubberizing top block is arranged at the bottom end of the rubberizing pressing block and used for supporting a tape material; and

the top rubber cylinder is connected with the eighth base, the top rubber cylinder is connected with the bottom end of the rubberizing ejector block, and the top rubber cylinder drives the rubberizing ejector block to move relative to the eighth chuck.

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